Optically resonant nanoantennae are key building blocks for metasurfaces, nanosensors and nanophotonic light sources due to their ability to control the amplitude, phase, directivity and polarization of scattered light. Here, we report an experimental technique for the full recovery of all degrees of freedom encoded in the far-field radiated by a single nanostructure using a high-NA Fourier microscope equipped with digital off-axis holography. This method enables full decomposition of antenna-physics in its multipole contributions and gives full access to the orbital and spin angular momentum properties of light scattered by single nano-objects. Our results demonstrate these capabilities through a quantitative assessment of the purity of the ‘selection rules’ for orbital angular momentum transfer by plasmonic spiral nanostructures.

Additional Metadata
Publisher Springer Nature
Funder NWO
Persistent URL dx.doi.org/10.1038/s41377-018-0059-0
Journal Light : Sci. Appl.
Citation
Röhrich, R, Hoekmeijer, C, Osorio, C.I, & Koenderink, A.F. (2018). Quantifying single plasmonic nanostructure far -fields with interferometric and polarimetric k-space microscopy. Light : Sci. Appl., 7, 65: 1–65:11. doi:10.1038/s41377-018-0059-0